SU1024873A1 - Non-regular raster obtaining device - Google Patents

Abstract

A DEVICE FOR PREPARING AN IRREGULAR RASTER containing a cathode ray tube with an optocoupler system and a scanner, an optical projection {optical system that connects the cathode ray screen and an exhibited photographic material placed on the surface of the supporting drum mounted on the Electromotive Shaft shaft and exposed to a photomaterial placed on the surface of the supporting drum mounted on the Electromotive Shaft shaft. , the video amplifier connected to the cathode of the cathode ray tube, which, together with the optical projection system, is mounted on a movable carriage mechanically connected to the micrometer screw, is installed on the motor shaft of an additional electric drive, the synchro generator and the block of the next deflection, so that, in order to obtain a reproducible irregular raster structure with more accurate reproduction of the specified gradation characteristics, and digital-analog unit, unit for automatic control of moving carriage movement with feedback sensor, automatic control unit for growing and carrier drum with feedback sensor, microraster generator and additional devices the clone system and the scanner, and the digital-analogue unit is designed as a raster cell generator, two storage devices, a control unit and laziness, a pseudo-random number sensor and a digital-analog converter, and the output of the pseudo-random number sensor connected to the control unit is connected to the input of a form-ram generator cells connected with the control unit and connected to the inputs of the first and second storage devices, the outputs of which are connected respectively to the first (L and second inputs of the control and with the first output connected via a digital-to-analog converter to the output of the video amplifier, with the second output connected via a microraster generator, and an additional scanner with an additional, tsD 4i fault by the driving system, the first output of the clock generator connected to the second input of the microraster GO M with the control unit, two oo of other outputs of the synchronizer are connected to the first inputs of the automatic control unit of the movement control of the moving carriage and the rotation of the carrier drum, to the second inputs of which respectively, the outputs of the feedback sensor of the movable carriage mounted on the micrometric screw shaft and the feedback sensor of the rotation of the carrier drum are connected, one output of the automatic control unit of the rotation of the carrier drum

Description

The second drive a is connected to the scanner through the follow deviation unit, while the output of the automatic control unit for moving the carriage is connected to an auxiliary electric drive.

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The invention relates to printing, technical photography and cinematography, in particular to devices for receiving images and rasterized images, and can be used to produce irregular reproducible rasters of reproducible structure with predetermined gradation characteristics.

Devices for producing an irregular raster are known, whose raster cells have an irregular structure, based on multiple copying of the structure of a coarse-grained film, as a result of which the irregularity of the raster corresponds to the granular structure of the light sensitive layer of the original film lj,

The disadvantages of such devices include the extreme complexity of the process of obtaining rasters, the low reproducibility of this process and the gradation distortions that arise when fabricating printing forms using such rasters due to significant etching of the raster elements due to their irregular radius configuration, low print run of printing forms, poor reproducibility of parameters of prints.

The closest in technical essence to the invention is a device for producing an irregular raster, comprising a cathode ray tube, an optical projection system, an exposed photographic material located on the surface of a carrier drum mounted on the shaft of the first electric drive, deflecting the cathode ray tube system, connected to the output of the follower deviation unit, wherein the cathode (modulator) of the cathode ray tube is electrically connected with the output of the video amplifier, and the cathode ray tube Bka with deflecting system and optical projecting

system mounted on a movable carriage mechanically connected with a micrometer screw mounted on the shaft of the second electric drive | 2,

The process of color separation of the original halftone image requires obtaining three color separated screened images, each with its own gradation characteristics.

Using the random law of electron beam deflection results in rasterized images with a non-coinciding geometric structure. When combined, this leads to a decrease in the clarity of the enlarged image, which is a disadvantage of the device operation.

The aim of the invention is to obtain a reproducible irregular raster structure with more accurate reproduction of predetermined gradation characteristics.

This goal is achieved by

that the device for obtaining an irregular raster, containing a cathode ray tube with a deflecting system and a scanner, an optical projection system, an interface screen of the cathode ray tube, and an exhibited photographic material placed on the surface of the supporting drum mounted on the shaft of the electric drive, video amplifier connected to the cathode of the electron-beam tpy6KH, which, together with the optical projection system, is mounted on a movable carriage mechanically connected to the micrometer screw, On the motor shaft of the auxiliary electric drive, the synchronizer and the follower deviation unit, the digital-analogue unit, the unit for automatic control of displacement, are introduced. nor a mobile carriage with a feedback sensor, an automatic control unit for the rotation of the loadbase, an Irabana with a feedback sensor, a microinstrution generator and an additional deflection system and a scanner. And the digital-analogue unit is designed as a raster cell generator, two memory devices control unit, a pseudo-random number sensor and a digital-to-analog converter, and the output of the pseudo-random number sensor associated with the control unit is connected to the input of the raster cell generator, connected to the control unit and connected to the inputs of the first and second storage devices, the outputs of which are connected respectively to the first and second inputs of the control unit1 with the first output connected via a digital-to-analog converter to the input of the video amplifier, with the second output connected through the microraster generator, and an additional scanner with an additional deflection system, the first output of the synchronous generator connected to the control unit, the other two are connected to the second input of the microraster generator the sync generator outputs are connected to the first inputs of the automatic control unit for moving the carriage and rotating the carrier drum, to the second inputs of which are connected respectively the outputs of the feedback sensor of the mobile carriage mounted on the micrometer screw shaft and the feedback sensor of the rotating drum, one output of the unit automatic. The rotation control of the carrier drum is connected to the power input, and the second is connected to the sweep unit through the follow deviation unit, and the output of the automatic movement control unit of the movable carriage is connected to the auxiliary electric drive. The drawing shows the functional scheme of the device for obtaining an irregular raster. The device comprises a cathode ray tube 1, an additional deflecting system 2, an additional sweep unit 3, a deflecting system 4, a sweep unit 5, an optical projecting system 6, photo material 7: a carrier drum 8, a first electric drive 9, a unit 10. automatic rotation control 34 cyu (ero drum 8, drum 11 feedback sensor 8, movable carriage 12, micrometer screw 13, second electric drive 1, automatic movable carriage 12 automatic control unit 15, movable carriage 12 feedback sensor 16, block to 17 following deviation, microraster generator 18, control block 19, synchronous generator 20, digital-to-analog converter 21, video amplifier 22, raster cell former 23, first storage device, second storage device 25, sensor 26 Pseudo-random numbers. the devices 2A and 25, the control unit 13, the raster cell driver 23, the pseudo-random number sensor 26 and the digital-to-analog converter 21 together constitute the digital-analog block. In this device, by varying the density distribution in the raster cell, it is possible to control the raster gradation characteristic regardless of the raster geometry, i.e. regardless of sharpness characteristics. The gradation characteristic of the irregular raster is expressed by the linear sweep function of the raster cell — the dependences D (f) of the optical density D of the raster on the number of the raster element R. The linear sweep is defined by a sequence of numbers. The raster cell former 23 is essentially a microproceed: litter, whose work is in. the combination with the pseudo-random number sensor 26 is carried out according to the following algorithm. An array of pseudo-random numbers P (i), ... N is generated, where N is the number of elements in the raster cell. The P (|) array is ordered by increasing P (i () .. & P (i). Assign the values of the linear sweep elements to the raster cell elements as follows: 1st raster cell element is D (i), 2- th -D (i2), Nth - D {i (). Pseudo-random numbers are obtained using the following recurrent formula p aP 4-c (modS), n 5-1 where a, c, S are some constants. Form a string of raster cells. Repeat n (1-3) K times. The photographic material is element-wise determined by video signals proportional to the values of the raster elements, reading element-wise n lines to form a broken line of the raster cells, then the next cell line is formed and the process is repeated. The interconnection of the units and units of the device for obtaining irregular rasters is as follows: the electron-beam tube 1, the deflecting system of which is associated with the scanning unit 5 and the additional deflecting system of which is connected with the additional scanning unit 3, is optically connected through an optical projecting system 6 with a photographic material 7 which is located on the surface of the carrier drum 8. The carrier drum B is installed on the axis of the first electric drive 9 connected to the output of the automatic control unit 10 of the carrier block The araban, to the first input of which is connected the output of the sync generator 2C, and to the second input to the output of the feedback sensor P installed on the carrier drum 8, is connected to the second output through the unit 17 of the following deviation the input of the unit 5 sweeps. The cathode ray tube 1 with a deflecting system k and an additional deflecting system 2 and an optical projection system 6 are mounted on a movable carriage 12 mechanically connected to the micrometer screw 13. The micrometer screw 13 is mechanically connected to the shaft (not shown ) the second electric drive I, connected to the output of the automatic control unit 15, to the first input of which the output of the synchronous generator 20 is connected, and to the second output of the feedback sensor 16 installed on the axis of the micrometer screw 13 Generator output and 18 micro rorastra connected to the control unit 19, is coupled to the input of the additional unit 3 scans. The output of the digital-to-analog converter 21 connected to the control unit 19 through the video amplifier 22 is connected to the cathode (modulator) of the e-beam tube 1. The output of the pseudo-random number sensor 26 connected to the control unit 19 is connected to the raster whose raster 23. ki associated with the control unit 19. The outputs of the raster cell imager 23 are connected to the corresponding inputs of the first storage device 2 and the second storage device 25. The outputs of the storage devices 2k and 25 are connected to the inputs of the control unit 19. The device operates as follows. The required raster parameters are entered from the keyboard (not shown) of the control unit 19: raster dimensions, raster cell dimensions, raster element size, raster linear sweep function, and at the end - the command to start operation. The control unit 19 transmits to the raster cell imaging unit 23 the size of the raster cell in the elements, the number of raster elements in the row and the raster scan function, starts the sensor 26 with pseudo-random numbers. Obtaining the next value from the pseudo-random number sensor 26, the raster cell imager 23 writes the generated raster cells to the first memory 2k, which are written as a raster cell line (the number of raster lines in the 2k memory device is equal to the number of raster cell lines). Having formed the whole. the raster cell line, the raster cell generator 23 informs the control unit 19 of this and begins to generate the next line of raster cells in the second storage device 25. The control unit 19 starts the synchro generator 20 and the microraster generator 18. The microraster generator 1C is designed to form the microstructure of the raster element on the screen of the cathode ray tube 1, which is then transferred with a predetermined reduction of the optical projection system 6 into the emulsion layer of the exposed photographic material 7. The size of the microinstrution forming the raster element is specified by the control unit 19 to the generator 18. The synchronous generator 20 includes a cathode-ray tube I and the first electric drive 9 of the carrier drum and, with the material 7 placed on it, and the second elec The mobile drive of the movable carriage 12, the purpose of which is to form a spiral scan of the spot cathode ray tube 1 on the surface of the photographic material 7. Next, the control unit 19, using signals from the synchro-generator 20, alternately selects the raster elements from the corresponding storage device 2 ((25 ) "Transmits this value to a digital-to-audio converter 21. The time of formation of the lines of raster cells in the first storage device 2k and in the second storage device 25 programs It is connected with the sampling time of these control units 19 from the second storage device 25 and the first storage device 2. The sampling time of information from the storage devices 2 (25) and the sensitometric characteristics of the exposed material 7 determine the rotational speed of the supporting drum B and the speed of movement of the movable carriage 12 along the drum 8. The instantaneous speed of rotation of the carrying drum 8 through the first electric drive 9 Pack. equals the automatic control unit 10, which processes the phase difference signal between the pulse removed from the output of the feedback sensor P installed at the drum 8 and the pulses from the synchronous generator 20. Similarly, the automatic control unit 15 of the moving carriage 12 operates, which fulfills the phase mismatch signal between the pulses coming from the output of the feedback sensor 1b installed on the shaft (not shown) of the micrometer screw 13 and from the synchrogen 20. The digital analog converter 21 converts the incoming values into a video signal, which, through the video amplifier 22, modulates the brightness of the screen of the cathode-ray tube 1. The control unit 19 performs a total count of the output lines of raster cells, upon reaching the required number of them, the cathode-ray tube 1 is turned off and device as a whole. The second output of the automatic displacement unit 10 of the carrier drum 8 is connected to the input of the follow-deviation unit 17, the purpose of which, together with the sweep unit 5 and the deflecting system t, is to form ramp current pulses of a duration equal to the generation time of the microrastra generator 18. These current pulses the microraster formed on the screen of the electron beam tube 1 is deflected in the direction of forming the tth row of the raster elements. As a result, the exposure microraste during the formation of the raster element turns out to be stationary with respect to the continuously moving photo material 7 on the surface of the carrying drum 8. The microrastation formed by the generator 18 is identical to the progressive television raster with damping line and frame sync pulses received from the synchro generator 20 ;. Densitometric measurements showed that the contrast of the rasterized wedge is 1.5 and its contrast corresponds to the specified gradation parameters of the raster, which were expressed by a linear sweep function. The absolute difference between the nonlinear programmed values in the raster and densitometrically measured values of the optical density of the wedge does not exceed 0.06 0. Thus, the resulting rasters can be used to rasterize images, obtaining the desired tone reproduction. Using masks screened on such a raster on a color film, it is possible to carry out color correction of images. Since the rasters obtained on the proposed device determine the inequality of the gradation characteristics of the rasterized images, the quality of the color correction is not lower than the quality of the correction on the electronic color correctors. At the same time, photographic rasterization of images using contact rasters is more productive and cheaper process than the rasterization process on electronic color correctors.

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Claims (1)

2. Kuznetsov Yu.V., Uzilevsky V.A. Electronic screening in printing. I., 1976, p.83-89 (prototype) ('54) (57) DEVICE FOR OBTAINING AN IRREGULAR RASTER, containing a cathode ray tube with a deflecting system and a scanning unit, an optical projecting system <conjugating the cathode-ray tube screen and the exposed photographic material placed on the surface of the carrier drum mounted on the shaft of the electric drive, a video amplifier connected to the cathode of the cathode ray tube, which, together with the optical projection system, is mounted on a movable carriage mechanically connected with a micrometer With a screw mounted on the shaft of the auxiliary electric motor engine, a synchro-generator and a tracking deviation unit, this is so that in order to obtain a reproducible structure of an irregular raster with more accurate reproduction of the specified gradation characteristics, a digital-analog block, block for automatically controlling the movement of the movable carriage with a feedback sensor, block for automatically controlling the rotation of the carrier drum with a feedback sensor, a micro-raster generator and complete nye deflection system and scanner, and a digital to analog unit is configured as a raster generator cell, two storage devices controlled _ώ Lenia block pseudorandom numbers and a digital to analog converter with the output of the sensor * pseudorandom number associated with a control blokog is connected to an input of the raster cell connected to the control unit and connected to the inputs of the first and second storage devices, the outputs of which are connected respectively to the first and second inputs of the control unit the first output connected via a digital-to-analog converter to the input of the video amplifier, with the second output connected via a micro-raster generator, and an additional scan unit with an additional · off. by the developing system, the first output of the sync generator connected to the control unit is connected to the second input of the microraster generator, the other two outputs of the synchronizer are connected to the first inputs of the automatic regulation of the movement of the movable carriage and the rotation of the carrier drum, the outputs of the feedback sensor of the movable carriage mounted respectively to their second inputs on the shaft of the micrometer screw, and the feedback sensor of rotation of the main drum, one output of the automatic rotation control unit carrier drum connected to the input electron .SU1024873 102 ^ 873 drives, and the second through the tracking deviation unit is connected to the sweep unit, the output of the block for automatically controlling the movement of the movable carriage is connected to an additional electric drive.